Enhancement of Photosynthetic Iron-Use Efficiency Is an Important Trait of Hordeum vulgare for Adaptation of Photosystems to Iron Deficiency

Saito, Akihiro; Shinjo, Shotaro; Ito, Daiki; Doi, Yuko; Sato, Akira; Wakabayashi, Yuna; Honda, Juma; Arai, Yuuki; Maeda, Tsubasa; Ohyama, Takuji; Higuchi, Kyoko

doi:10.3390/plants10020234

Cited by 13 publications

(30 citation statements)

References 56 publications

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“…In accordance with these results that confirm the importance of Fe use efficiency in shoots, Zhao et al ( 2020 ) suggested that the iron efficiency is attributed to an iron activation mechanism in leaves. Saito et al ( 2021 ) demonstrated that varieties of barley originating from alkaline soils increased their photosynthetic iron use efficiency in response to Fe‐deficiency. They suggest that the ability of Fe‐deficiency tolerant varieties of barley to increase their iron use efficiency is related to optimizing the electron flow downstream of PSII, including cytochrome b6f and photosystem I. Hantzis et al ( 2018 ) and Kroh and Pilon ( 2020 ) suggested that cyt b6f and PSI are the most Fe‐requiring photosynthetic apparatus and the primary sufferer of Fe‐deficiency in plants.…”

Section: Discussionmentioning

confidence: 99%

“…They suggest that the ability of Fe‐deficiency tolerant varieties of barley to increase their iron use efficiency is related to optimizing the electron flow downstream of PSII, including cytochrome b6f and photosystem I. Hantzis et al ( 2018 ) and Kroh and Pilon ( 2020 ) suggested that cyt b6f and PSI are the most Fe‐requiring photosynthetic apparatus and the primary sufferer of Fe‐deficiency in plants. Saito et al ( 2021 ) postulate that the key mechanism for increased photosynthesis iron use efficiency under Fe‐deficiency to exist downstream of PSII seems reasonable. Nevertheless, Durum wheat is known by its capacity of roots release exudates into the rhizosphere (strategy II plant releasing PS).…”

Section: Discussionmentioning

confidence: 99%

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Genotypic differences in response of durum wheat (Triticum durum Desf.) to lime‐induced iron chlorosis

Salhi

Hajlaoui²,

Krouma

2022

Plant Direct

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Wheat, durum wheat, is the first cereal cultivated and consumed in Tunisia. Because the dominance of calcareous soils in its agroecological systems, known by their low availability of iron (Fe) inducing Fe chlorosis and limiting crop production, its yield remains low. Therefore, the search for tolerant genotypes is always current. In this context, the physiological behavior of six Tunisian genotypes of durum wheat (salim, karim, razek, khiar, inrat100, and maali) cultivated on calcareous and fertile soils for 2 months in a pot experiment was investigated. A greenhouse was used to conduct experiments under natural light. Plant growth, SPAD index, Fe nutrition, Fe distribution, and photosynthesis were monitored and used to evaluate and discriminate their respective physiological responses. On calcareous soil, results revealed reduced plant growth, active Fe, SPAD index, and net photosynthesis. Genotypic differences in the response of wheat to calcareous‐induced Fe deficiency were observed and allowed to classify the genotypes Salim and Karim as relatively tolerant. These genotypes expressed Fe translocation capacity (FeT) up to 3 times, Fe use efficiency for photosynthesis (FeUEAn) up to 1.6 times, and chlorophyll use efficiency for photosynthesis (ChlUEAn) up to 3.5 times greater than that expressed by the other genotypes, particularly inrat100 and maali. Thus, the relative tolerance of Salim and Karim is the result of the high ability of Fe uptake and translocation to shoots to support chlorophyll biosynthesis, photosynthesis, and plant growth as well as an important Fe and chlorophyll use efficiency.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Genotypic differences in response of durum wheat (Triticum durum Desf.) to lime‐induced iron chlorosis

Salhi

Hajlaoui²,

Krouma

2022

Plant Direct

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“…However, the actual Fe uptake rate has not been broadly surveyed in many species or genotypes using the same experimental system. We recently reported that the amount of acquired Fe may not always be the sole determinant of tolerance to Fe deficiency, and that acclimation of chloroplasts to low-Fe conditions also contributes to tolerance among barley cultivars [ 11 ]. Some Fe-deficiency-tolerant cultivars may exert tolerance depending on the effective Fe uptake, whereas others depend on Fe sparing.…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, the fluorescent material was replaced to obtain better luminescence because the uptake of trace elements, such as Fe, was low. The three barley cultivars used in this work were “Sarab 1 (SRB)” with very strong Fe-deficiency tolerance, “Ehimehadaka 1 (EHM)” with strong tolerance, and “Ethiopia 2 (ETH)” with weak tolerance [ 11 ]. SPAD values of EHM and ETH significantly decreased when cultivated with 3 μM Fe nutrient solution and ETH exhibited very severe chlorosis with 1 μM Fe, whereas SRB showed no obvious chlorosis even under the 1 μM Fe condition ( Figure 1 in [ 11 ]).…”

Section: Introductionmentioning

confidence: 99%

“…The three barley cultivars used in this work were “Sarab 1 (SRB)” with very strong Fe-deficiency tolerance, “Ehimehadaka 1 (EHM)” with strong tolerance, and “Ethiopia 2 (ETH)” with weak tolerance [ 11 ]. SPAD values of EHM and ETH significantly decreased when cultivated with 3 μM Fe nutrient solution and ETH exhibited very severe chlorosis with 1 μM Fe, whereas SRB showed no obvious chlorosis even under the 1 μM Fe condition ( Figure 1 in [ 11 ]). We show that one of the tolerant cultivars, EHM, showed excellent Fe absorption, whereas the cultivar SRB acquired a smaller amount of Fe than the Fe-deficiency sensitive cultivar ETH.…”

Section: Introductionmentioning

confidence: 99%

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“Live-Autoradiography” Technique Reveals Genetic Variation in the Rate of Fe Uptake by Barley Cultivars

Higuchi

Kurita

Sakai

et al. 2022

Plants

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Iron (Fe) is an essential trace element in plants; however, the available Fe in soil solution does not always satisfy the demand of plants. Genetic diversity in the rate of Fe uptake by plants has not been broadly surveyed among plant species or genotypes, although plants have developed various Fe acquisition mechanisms. The “live-autoradiography” technique with radioactive 59Fe was adopted to directly evaluate the uptake rate of Fe by barley cultivars from a nutrient solution containing a very low concentration of Fe. The uptake rate of Fe measured by live autoradiography was consistent with the accumulation of Fe-containing proteins on the thylakoid membrane. The results revealed that the ability to acquire Fe from the low-Fe solution was not always the sole determinant of tolerance to Fe deficiency among barley genotypes. The live-autoradiography system visualizes the distribution of β-ray-emitting nuclides and has flexibility in the shape of the field of view. This technique will strongly support phenotyping with regard to the long-distance transport of nutrient elements in the plant body.

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Silicon (Si) Alleviates Iron Deficiency Effects in Sea Barley (Hordeum marinum) by Enhancing Iron Accumulation and Photosystem Activities

Ksiaa

Farhat

Rabhi

et al. 2021

Silicon

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Enhancement of Photosynthetic Iron-Use Efficiency Is an Important Trait of Hordeum vulgare for Adaptation of Photosystems to Iron Deficiency

Cited by 13 publications

References 56 publications

Genotypic differences in response of durum wheat (Triticum durum Desf.) to lime‐induced iron chlorosis

Genotypic differences in response of durum wheat (Triticum durum Desf.) to lime‐induced iron chlorosis

“Live-Autoradiography” Technique Reveals Genetic Variation in the Rate of Fe Uptake by Barley Cultivars

Silicon (Si) Alleviates Iron Deficiency Effects in Sea Barley (Hordeum marinum) by Enhancing Iron Accumulation and Photosystem Activities

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